Device for detecting and displaying one or more of body weight, body fat percentage, blood pressure, pulse and environmental temperature
A device for measuring and displaying body parameters includes a sensor that generates a signal representing a detected body parameter, such as body fat, body water and weight, and blood pressure of an individual; a transmitter to wirelessly transmit the signal; a receiver to receiver and display the sensed measurements as well as a user's name, time, date and temperature. The invention also pertains a method for determining fitness comprising the steps of: inputting, data pertaining to one of date, time, an individual's name, and fitness statistics, sensing parameters of one or more of a body fat, a body water, blood pressure and a weight; recording sensed parameters and said data; and transmitting the sensed parameters and said data; receiving said sensed parameters and said data and a signal proportional to a temperature and displaying one or more of said sensed parameters, data and temperature on a portable display unit.
This application claims priority of U.S. Patent Application Ser. No. 60/859,221, entitled WEIGHING SCALE, filed Nov. 15, 2006, the entire disclosure of which is hereby incorporated by reference as if being set forth in its entirety herein.
FIELD OF THE INVENTIONThis application relates generally to weighing scales and to body sensors.
BACKGROUND OF THE INVENTIONBathroom scales for measuring body fat and weight are known apparatuses used by the general public and particularly individuals that are fitness conscious. Weight alone does not provide an accurate assessment of an individual's fitness or progress in attaining fitness. For fitness conscious individuals, body fat measurements, in addition to body weight, may improve their assessment of their progress toward reaching, and their diligence in maintaining, fitness goals. Accuracy and reliability depend to some degree on using the same measurement devices. However, the prior art lacks a low cost device that will accurately monitor several bodily parameters over time that also uses the same technique to observe and record associated changes in parameters such as body fat, weight and body water percentage. Additionally, in order to make body fat and body water percentage or water readings are more accurate, it is helpful to have a general category of “fitness level”. Although the prior art deals with one or another aspect of fitness, none deals with the capability of having a broad range of salient statistics available in the scale and in a hand held device that can be up-dated to suit individual users.
Electronic blood pressure measuring devices typically automatically apply pressure via a pump to inflate the arm cuff. The inflation pump contains a one-way valve to prevent inadvertent pressure leaks while other mechanisms allow the pressure in the system to drop in a controlled manner. In the typical mode of operation, the cuff is placed around part of the arm. In some applications the cuff is placed approximately one-half inch above the elbow at roughly the same vertical height as the heart while the individual is in an upright position. In other devices the cuff may be placed around the wrist. The cuff is inflated until the artery within the arm is blocked off. Once the blood flow is blocked cuff pressure is gradually decreased using electrically controlled valves. As the pressure in the cuff diminishes, blood begins to flow through the previously blocked off artery. As indicated in the prior art sounds of the blood initially flowing at or near the time the initial deflation occurs and later, when blood flow resumes its normal state blood pressure is determined. The pressure sensed at the onset of blood flow is referred to as the systolic blood pressure. As cuff pressure continues to decrease a steady state pressure is reached and is referred to as the diastolic blood pressure. In certain conventional electronic blood pressure monitors blood pressure is calculated according relationships between average and peak widths of a pulsed wave detected when the cuff is pressurized and depressurized. The prior art digital blood pressure meters use determine blood pressure and register the data on a digital read out. These read outs are integrally connected to the meters which are not practicably portable.
SUMMARY OF THE INVENTIONAccording to an aspect of the present invention, a weighing scale utilizes a body fat sensor, a body water sensor and a weight sensor coupled to a processor having therein contained a program to record fitness level, display the sensed parameters and transmit the parameters to a portable display unit. The combined sets of readings comprise a statistical set that may be combined to produce a level of fitness for individual users. The weighing scale also includes a “weight only” function that allows the body fat scale to also be used as a typical bathroom scale.
In yet another embodiment a device measures body fat and body water percentages, and tracks weight to show the individuals target or goal weight and the difference between the goal and the current weight.
In one embodiment a wireless display unit is attachable and detachable from the scale. When the display unit is removed from the scale it can be hand held or placed on a wall or flat surface. An exclusive remote sensor reads the outside temperature and time, which is transmitted the scale periodically and displayed when scale or the portable unit is not being used. The scale and the display unit contain memory devices to record and store statistical information such as time, date and an identifier related to personal data such as the individual's name, and the associated fitness statistics received. In yet another embodiment, the scale and the display device include corresponding pass codes to protect the personal data of a particular user and to authenticate the identity of the user.
The invention disclosed herein also includes a method for utilizing a body fat sensor, body water sensor and a weight sensor coupled to a processor having therein contained a program to record a fitness level: providing a scale for individuals to obtain measurements for one or more of an individual's body fat, body water and weight; generating one or more output signals proportional to the one or more of body fat measurement, body water measurement and weight measurement; and transmitting the one or more outputs to a receiver for displaying the measurements.
According to an aspect of the present invention, a blood pressure monitor generates an output signal proportional to the systolic blood pressure and the diastolic blood pressure and transmits the signal to a remote receiver that includes a processor and memory code operable calculate and to record blood pressure and pulse, and other statistical information such as time, date and an identifier related to the user's name and indicative of a level of wellness for individual users.
In yet another embodiment a blood pressure or pulse rate system comprises one or more blood pressure or pulse rate meters, each having a plurality of sensors that generate a plurality of output signals proportional to one or more of a sensed blood pressure, pulse rate and a means to sense temperature; each sensor having a means to communicate to one or more associated portable display units; each said portable display unit including a means to receive and a processor code operable to calculate a measure of blood pressure or pulse rate based upon the output signal data and input data pertaining to vital statistics of each user; and displaying the blood pressure, pulse rate and temperature.
In yet another embodiment, the remote device includes corresponding pass codes to protect the personal data of a particular user and to authenticate the identity of the user. A remote sensor also reads the outside temperature and time, which is transmitted a wireless remote unit to periodically display the temperature and time when the portable unit is not being used to record blood pressure or pulse rate.
In the figures to be discussed, the circuits and associated blocks and arrows represent functions of the process according to the present invention, which may be implemented as electrical circuits and associated wires or data busses, which transport electrical signals. Alternatively, one or more associated arrows may represent communication (e.g., data flow) between software routines, particularly when the present method or apparatus of the present invention is a digital process.
Referring to
Portable display unit 104 is removable from scale 101, and may be housed, as illustrated in
As illustrated schematically in
Processor 112 is also coupled to wireless transmitter 120.
Referring to
Each of scale 101, temperature sensing unit 105, and blood pressure unit 106 may include a processor, memory, and wireless transmitter. Readings obtained from any of these units may be wirelessly transmitted to receiver 420 of
Referring now to
Switch 24 in association with the start/stop circuit causes pump 530 to pump air via line 534 through check valve 536 and through line 538 to inflate bladder 540. Sensor 537 is in contact with a surface of bladder 540 and senses pressure P. A reading from sensor 537 may be provided to a processor, as explained above, which may provide a signal to disable pump 530. Such signal may, by way of example, turn off start/stop circuit 532 stopping the pump 530 or causing electronic solenoid 531 to disable check valve 536 when the pressure P reaches a designed pressure, such as approximately 195 mm HG. Under the pressure P of inflated arm band bladder 540, an arm is constricted and blood flow through arm in the area where apparatus 500 is mounted is reduced or cut off. Having attained the proper level of applied arm pressure P, valve 542 under control of valve controller 533 housed in apparatus 500 slowly allows pressure P in armband bladder 540 to dissipate or exhaust air through port 549. As the blood is allowed to resume flow, sensor 50 detects the higher systolic blood pressure and the lower diastolic blood pressure. The two sensed blood pressure readings serve as input to a processor, which then provides the data to display 512, so as to display the two pressures as systolic blood pressure 518 and diastolic blood pressure 516, as seen in
In addition to sensing systolic blood pressure and diastolic blood pressure, apparatus 500 also detects the pulse rate 514. A pressure sensor, which may be in a position to be in contact with the person's arm, provides a continuous or periodic pressure signal to a processor, which analyzes and determines a pulse rate 514 based on the varying pressure signal received. The processor outputs the pulse rate 514 to display 512, and may also cause the pulse rate 514 to be wireless transmitted for reception at base unit 104. An additional sensor, which may read, for example, skin temperature, may also be provided. The optionally sensed input serves as input to processor 70, which processes code that formats and outputs the optionally sensed data to display 12.
Referring again to
As will be apparent from the foregoing a designer of a system incorporating the scale, temperature unit, blood pressure unit, and the portable display 104, needs to decide where to include certain functions as performed by the combination of the two devices. For example, when the portable unit 104 is installed in the scale 101, a single processor may serve the roles of both processor 112 and processor 410. If the portable display unit 104 has been detached from the scale 101, the scale 101 must include a means for transmitting the sensor data to the display unit 104. Therefore, where to accomplish the processing of the sensor data, input data related to fitness statistics and temperature is a design choice.
Returning to the scale 101 that includes a processor 112, the processor is generally a microprocessor that includes a memory 118 for storing one or more measurements including inputs from load cells and body fat sensors, and may also store outside temperature and key data from unit 104 and statistical information such as time, date and an identifier for related to the user's name. The processor 112 permits settings related to receiving input sensor data, storing the data, retrieving the data and other information such as the statistics recorded in memory 118 and communicating with display unit 104 and alternatively transceiver 110. The reference to transceiver refers to any device capable of transmitting and/or receiving. Whether the receiver and transmitters are integrated or not is a design choice and does not alter the intents supporting the invention herein.
In some embodiments, outside temperature is sensed by a thermometer which has an associated transmitter that periodically communicates the outside temperature the receiver of base unit 104, which is then received by the processor, which then displays, and may store, the temperature. Upon receiving the information related to one or more of the body fat measure, body water measure and weight measure as determined from the scale 101, the processor 410 may cause this data to be stored, such as in memory 430. Memory 410 may include stored measurements including statistical information such as time, date, outside temperature, an identifier related to the user's name, age, height and the associated weight, body fat and body water percentage received. The key input 108 interfaces with the processor 410 to permit settings related to storing weights, retrieving information such as the statistics recorded in memory 180 and displaying the statistics.
According to an aspect of the present invention, a wired connection may be provided between scale 101 and base unit 104, when base unit 104 is located in scale 101, as shown in
The invention herein is not limited to a single receiver in the base unit, but may include communications with one or more receivers depending on the particular application. For non-limiting purposes of explanation, in one embodiment the transmitter 150 communicates with the transceiver 165 within the associated display unit 104 up to sixty (30′) feet from the point of measurement.
In an alternate embodiment the invention the portable unit 104 may receive communication from one or more scales 101 distributed at different locations. The convenience factor is that an individual may carry the portable unit 104 from place to place and have the benefit of determining fitness if a scale 101 were available. The user may by way of non-limiting example, install the portable unit 104 into the scale 101 and proceed to make the measurements as previously indicated. Alternatively, the user may choose to keep the portable unit 104 removed from the scale 101, and make the measurements as previously indicated, in which case the scale 101 would transmit the measurements to the portable unit 104. In this application the scale system 100 comprises one or more scales 101, each having load cells and units for determining body fat, body water percentage, and/or temperature. Each may have a transmitter for communicating the output signals to one or more associated portable display units 104; each said portable display unit 104 including a means to receive and a processor to calculate a measure of fitness based upon the output signals and inputs pertaining to vital statistics of each user; and displaying the output signals and inputs.
Those skilled in the art of computer programming will appreciate that the invention may be implemented in a system of computer units or processors communicatively coupled to one another over a network, such as a wide area network. “Processor”, as used herein, refers generally to a computing device such as a microprocessor having a CPU. A CPU generally includes an arithmetic logic unit (ALU), which performs arithmetic and logical operations, and a control unit, which extracts instructions (e.g., code) from memory and decodes and executes them, calling on the ALU when necessary. “Memory”, as used herein, refers to one or more devices capable of storing data, such as in the form of chips, tapes, disks or drives. Memory may take the form of one or more random-access memory (RAM), read-only memory (ROM), programmable read-only memory (PROM), erasable programmable read-only memory (EPROM), or electrically erasable programmable read-only memory (EEPROM) chips, by way of further non-limiting example only. Memory may be internal or external to an integrated unit including a processor. Memory may be internal or external to an integrated unit including a personal computer. Memory unit preferably stores a computer program, e.g., sequence of instructions being operable by the processor.
The invention herein also includes a method for weighing comprising the steps of: providing a scale for individuals to obtain measurements for one or more of an individual's body fat, body water and weight; generating one or more output signals proportional to the one or more of body fat measurement, body water measurement and weight measurement; and transmitting the one or more outputs and receiving the outputs and displaying the measurements.
The invention herein also includes a method of inputting, data pertaining to one of date, time, an individual's name, and fitness statistics, sensing parameters of one or more of a body fat, body water and weight; recording the sensed parameters and said data; and transmitting the sensed parameters and said data; receiving said sensed parameters and said data and a signal proportional to a temperature and displaying one or more of said sensed parameters, data and temperature on the portable display unit.
While the present invention has been described with reference to the illustrative embodiments, this description is not intended to be construed in a limiting sense. Various modifications of the illustrative embodiments, as well as other embodiments of the invention, will be apparent to those skilled in the art on reference to this description. It is expressly intended that all combinations of those elements that perform substantially the same function in substantially the same way to achieve the same results are within the scope of the invention. Substitutions of elements from one described embodiment to another are also fully intended and contemplated.
Claims
1. An apparatus for monitoring a plurality of bodily parameters, said apparatus comprising: wherein said processor contains computer code, said code causes the outputs of said body fat, body water and weight sensors to be recorded in said memory and to be displayed by said display.
- a scale having a platform comprising: a body fat sensor; a body water sensor; and a weight sensor for sensing a load on the platform;
- a display unit;
- a processor coupled to said body fat, body water and weight sensors; and
- a memory coupled to said processor
2. The apparatus of claim 1, wherein said display unit is attachable and detachable from said apparatus and is adapted to wirelessly communicate with said processor.
3. The apparatus of claim 1, further comprising a temperature sensing unit adapted to measure and display outside temperature and time.
4. The apparatus of claim 1, wherein said processor further comprises computer code which causes to be recorded in said memory, information including time, date and an identifier unique to an individual along with outputs of said body fat, body water and weight sensors for the individual.
5. The apparatus of claim 1, wherein said processor further comprises computer code to authenticate an individual before said processor causes personal information to be displayed on said display.
6. The apparatus of claim 1, further comprising a blood pressure monitor, wherein said blood pressure monitor is adapted to generate an output signal indicative of the systolic blood pressure and the diastolic blood pressure of an individual.
7. A method for measuring and storing a plurality of bodily parameters, said method comprising the steps of:
- providing a scale for an individual to obtain measurements for the individual's body fat, body water and weight;
- generating output signals proportional to body fat measurement, body water measurement and weight measurement; and
- wirelessly transmitting said one or more outputs to a receiver for displaying said measurements.
8. The method of claim 7, further comprising the steps of:
- detecting systolic and diastolic blood pressure of an individual;
- detecting pulse rate of the individual; and
- providing an output indicative of the measured systolic and diastolic blood pressure and the measured pulse rate.
9. The method of claim 8, further comprising the steps of:
- wirelessly transmitting the measured systolic and diastolic blood pressure and the measured pulse rate; and
- displaying the measured systolic and diastolic blood pressure and the measured pulse rate.
Type: Application
Filed: Nov 14, 2007
Publication Date: Jul 31, 2008
Patent Grant number: 7831408
Inventor: Steven Petrucelli (Cranbury, NJ)
Application Number: 11/985,345
International Classification: G06F 19/00 (20060101); A61B 5/02 (20060101);